Resynchronizing Jittery AES Power Traces

What happens if things aren't as clean as we made them out to be? We can use preprocessing modules!

In [1]:
SCOPETYPE = 'OPENADC'
PLATFORM = 'CWLITEARM'
CRYPTO_TARGET = 'TINYAES128C'
num_traces = 250
CHECK_CORR = False

Capturing Jittery Traces

Rebuilding New Firmware

In file chipwhisperer/hardware/victims/firmware/simpleserial-aes/simpleserial-aes.c find this:

uint8_t get_pt(uint8_t* pt)
{
    trigger_high();
    aes_indep_enc(pt); /* encrypting the data block */
    trigger_low();
    simpleserial_put('r', 16, pt);
    return 0x00;
}

and add some random delay:

uint8_t get_pt(uint8_t* pt)
{
    trigger_high();
       for(volatile uint8_t k = 0; k < (*pt & 0x0F); k++);
    aes_indep_enc(pt); /* encrypting the data block */
    trigger_low();
    simpleserial_put('r', 16, pt);
    return 0x00;
}

This deterministic delay is NOT a good countermeasure, but is much easier to write in a single line since we don’t have a CSPRNG linked in. We’ll break the jitter without relying on the deterministic aspect though, so our attack would work against a better jitter source.

Be sure to remove this function afterwards so you don't break your code!

We can build the code (change the platform as needed), and confirm the output of the following works as you expect:

In [2]:
%%bash -s "$PLATFORM" "$CRYPTO_TARGET"
cd ../hardware/victims/firmware/simpleserial-aes
make PLATFORM=$1 CRYPTO_TARGET=$2 EXTRA_OPTS=ADD_JITTER
rm -f -- simpleserial-aes-CWLITEARM.hex

rm -f -- simpleserial-aes-CWLITEARM.eep

rm -f -- simpleserial-aes-CWLITEARM.cof

rm -f -- simpleserial-aes-CWLITEARM.elf

rm -f -- simpleserial-aes-CWLITEARM.map

rm -f -- simpleserial-aes-CWLITEARM.sym

rm -f -- simpleserial-aes-CWLITEARM.lss

rm -f -- objdir/*.o

rm -f -- objdir/*.lst

rm -f -- simpleserial-aes.s simpleserial.s stm32f3_hal.s stm32f3_hal_lowlevel.s stm32f3_sysmem.s aes.s aes-independant.s

rm -f -- simpleserial-aes.d simpleserial.d stm32f3_hal.d stm32f3_hal_lowlevel.d stm32f3_sysmem.d aes.d aes-independant.d

rm -f -- simpleserial-aes.i simpleserial.i stm32f3_hal.i stm32f3_hal_lowlevel.i stm32f3_sysmem.i aes.i aes-independant.i

.

-------- begin --------

arm-none-eabi-gcc (GNU Tools for Arm Embedded Processors 7-2018-q2-update) 7.3.1 20180622 (release) [ARM/embedded-7-branch revision 261907]

Copyright (C) 2017 Free Software Foundation, Inc.

This is free software; see the source for copying conditions.  There is NO

warranty; not even for MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.



.

Compiling C: simpleserial-aes.c

arm-none-eabi-gcc -c -mcpu=cortex-m4 -I. -DADD_JITTER -mthumb -mfloat-abi=hard -mfpu=fpv4-sp-d16 -fmessage-length=0 -ffunction-sections -gdwarf-2 -DSS_VER=SS_VER_1_1 -DSTM32F303xC -DSTM32F3 -DSTM32 -DDEBUG -DHAL_TYPE=HAL_stm32f3 -DPLATFORM=CWLITEARM -DTINYAES128C -DF_CPU=7372800UL -Os -funsigned-char -funsigned-bitfields -fshort-enums -Wall -Wstrict-prototypes -Wa,-adhlns=objdir/simpleserial-aes.lst -I.././simpleserial/ -I.././hal -I.././hal/stm32f3 -I.././hal/stm32f3/CMSIS -I.././hal/stm32f3/CMSIS/core -I.././hal/stm32f3/CMSIS/device -I.././hal/stm32f4/Legacy -I.././crypto/ -I.././crypto/tiny-AES128-C -std=gnu99 -MMD -MP -MF .dep/simpleserial-aes.o.d simpleserial-aes.c -o objdir/simpleserial-aes.o 

.

Compiling C: .././simpleserial/simpleserial.c

arm-none-eabi-gcc -c -mcpu=cortex-m4 -I. -DADD_JITTER -mthumb -mfloat-abi=hard -mfpu=fpv4-sp-d16 -fmessage-length=0 -ffunction-sections -gdwarf-2 -DSS_VER=SS_VER_1_1 -DSTM32F303xC -DSTM32F3 -DSTM32 -DDEBUG -DHAL_TYPE=HAL_stm32f3 -DPLATFORM=CWLITEARM -DTINYAES128C -DF_CPU=7372800UL -Os -funsigned-char -funsigned-bitfields -fshort-enums -Wall -Wstrict-prototypes -Wa,-adhlns=objdir/simpleserial.lst -I.././simpleserial/ -I.././hal -I.././hal/stm32f3 -I.././hal/stm32f3/CMSIS -I.././hal/stm32f3/CMSIS/core -I.././hal/stm32f3/CMSIS/device -I.././hal/stm32f4/Legacy -I.././crypto/ -I.././crypto/tiny-AES128-C -std=gnu99 -MMD -MP -MF .dep/simpleserial.o.d .././simpleserial/simpleserial.c -o objdir/simpleserial.o 

.

Compiling C: .././hal/stm32f3/stm32f3_hal.c

arm-none-eabi-gcc -c -mcpu=cortex-m4 -I. -DADD_JITTER -mthumb -mfloat-abi=hard -mfpu=fpv4-sp-d16 -fmessage-length=0 -ffunction-sections -gdwarf-2 -DSS_VER=SS_VER_1_1 -DSTM32F303xC -DSTM32F3 -DSTM32 -DDEBUG -DHAL_TYPE=HAL_stm32f3 -DPLATFORM=CWLITEARM -DTINYAES128C -DF_CPU=7372800UL -Os -funsigned-char -funsigned-bitfields -fshort-enums -Wall -Wstrict-prototypes -Wa,-adhlns=objdir/stm32f3_hal.lst -I.././simpleserial/ -I.././hal -I.././hal/stm32f3 -I.././hal/stm32f3/CMSIS -I.././hal/stm32f3/CMSIS/core -I.././hal/stm32f3/CMSIS/device -I.././hal/stm32f4/Legacy -I.././crypto/ -I.././crypto/tiny-AES128-C -std=gnu99 -MMD -MP -MF .dep/stm32f3_hal.o.d .././hal/stm32f3/stm32f3_hal.c -o objdir/stm32f3_hal.o 

.

Compiling C: .././hal/stm32f3/stm32f3_hal_lowlevel.c

arm-none-eabi-gcc -c -mcpu=cortex-m4 -I. -DADD_JITTER -mthumb -mfloat-abi=hard -mfpu=fpv4-sp-d16 -fmessage-length=0 -ffunction-sections -gdwarf-2 -DSS_VER=SS_VER_1_1 -DSTM32F303xC -DSTM32F3 -DSTM32 -DDEBUG -DHAL_TYPE=HAL_stm32f3 -DPLATFORM=CWLITEARM -DTINYAES128C -DF_CPU=7372800UL -Os -funsigned-char -funsigned-bitfields -fshort-enums -Wall -Wstrict-prototypes -Wa,-adhlns=objdir/stm32f3_hal_lowlevel.lst -I.././simpleserial/ -I.././hal -I.././hal/stm32f3 -I.././hal/stm32f3/CMSIS -I.././hal/stm32f3/CMSIS/core -I.././hal/stm32f3/CMSIS/device -I.././hal/stm32f4/Legacy -I.././crypto/ -I.././crypto/tiny-AES128-C -std=gnu99 -MMD -MP -MF .dep/stm32f3_hal_lowlevel.o.d .././hal/stm32f3/stm32f3_hal_lowlevel.c -o objdir/stm32f3_hal_lowlevel.o 

.

Compiling C: .././hal/stm32f3/stm32f3_sysmem.c

arm-none-eabi-gcc -c -mcpu=cortex-m4 -I. -DADD_JITTER -mthumb -mfloat-abi=hard -mfpu=fpv4-sp-d16 -fmessage-length=0 -ffunction-sections -gdwarf-2 -DSS_VER=SS_VER_1_1 -DSTM32F303xC -DSTM32F3 -DSTM32 -DDEBUG -DHAL_TYPE=HAL_stm32f3 -DPLATFORM=CWLITEARM -DTINYAES128C -DF_CPU=7372800UL -Os -funsigned-char -funsigned-bitfields -fshort-enums -Wall -Wstrict-prototypes -Wa,-adhlns=objdir/stm32f3_sysmem.lst -I.././simpleserial/ -I.././hal -I.././hal/stm32f3 -I.././hal/stm32f3/CMSIS -I.././hal/stm32f3/CMSIS/core -I.././hal/stm32f3/CMSIS/device -I.././hal/stm32f4/Legacy -I.././crypto/ -I.././crypto/tiny-AES128-C -std=gnu99 -MMD -MP -MF .dep/stm32f3_sysmem.o.d .././hal/stm32f3/stm32f3_sysmem.c -o objdir/stm32f3_sysmem.o 

.

Compiling C: .././crypto/tiny-AES128-C/aes.c

arm-none-eabi-gcc -c -mcpu=cortex-m4 -I. -DADD_JITTER -mthumb -mfloat-abi=hard -mfpu=fpv4-sp-d16 -fmessage-length=0 -ffunction-sections -gdwarf-2 -DSS_VER=SS_VER_1_1 -DSTM32F303xC -DSTM32F3 -DSTM32 -DDEBUG -DHAL_TYPE=HAL_stm32f3 -DPLATFORM=CWLITEARM -DTINYAES128C -DF_CPU=7372800UL -Os -funsigned-char -funsigned-bitfields -fshort-enums -Wall -Wstrict-prototypes -Wa,-adhlns=objdir/aes.lst -I.././simpleserial/ -I.././hal -I.././hal/stm32f3 -I.././hal/stm32f3/CMSIS -I.././hal/stm32f3/CMSIS/core -I.././hal/stm32f3/CMSIS/device -I.././hal/stm32f4/Legacy -I.././crypto/ -I.././crypto/tiny-AES128-C -std=gnu99 -MMD -MP -MF .dep/aes.o.d .././crypto/tiny-AES128-C/aes.c -o objdir/aes.o 

.

Compiling C: .././crypto/aes-independant.c

arm-none-eabi-gcc -c -mcpu=cortex-m4 -I. -DADD_JITTER -mthumb -mfloat-abi=hard -mfpu=fpv4-sp-d16 -fmessage-length=0 -ffunction-sections -gdwarf-2 -DSS_VER=SS_VER_1_1 -DSTM32F303xC -DSTM32F3 -DSTM32 -DDEBUG -DHAL_TYPE=HAL_stm32f3 -DPLATFORM=CWLITEARM -DTINYAES128C -DF_CPU=7372800UL -Os -funsigned-char -funsigned-bitfields -fshort-enums -Wall -Wstrict-prototypes -Wa,-adhlns=objdir/aes-independant.lst -I.././simpleserial/ -I.././hal -I.././hal/stm32f3 -I.././hal/stm32f3/CMSIS -I.././hal/stm32f3/CMSIS/core -I.././hal/stm32f3/CMSIS/device -I.././hal/stm32f4/Legacy -I.././crypto/ -I.././crypto/tiny-AES128-C -std=gnu99 -MMD -MP -MF .dep/aes-independant.o.d .././crypto/aes-independant.c -o objdir/aes-independant.o 

.

Assembling: .././hal/stm32f3/stm32f3_startup.S

arm-none-eabi-gcc -c -mcpu=cortex-m4 -I. -x assembler-with-cpp -mthumb -mfloat-abi=hard -mfpu=fpv4-sp-d16 -fmessage-length=0 -ffunction-sections -DF_CPU=7372800 -Wa,-gstabs,-adhlns=objdir/stm32f3_startup.lst -I.././simpleserial/ -I.././hal -I.././hal/stm32f3 -I.././hal/stm32f3/CMSIS -I.././hal/stm32f3/CMSIS/core -I.././hal/stm32f3/CMSIS/device -I.././hal/stm32f4/Legacy -I.././crypto/ -I.././crypto/tiny-AES128-C .././hal/stm32f3/stm32f3_startup.S -o objdir/stm32f3_startup.o

.

Linking: simpleserial-aes-CWLITEARM.elf

arm-none-eabi-gcc -mcpu=cortex-m4 -I. -DADD_JITTER -mthumb -mfloat-abi=hard -mfpu=fpv4-sp-d16 -fmessage-length=0 -ffunction-sections -gdwarf-2 -DSS_VER=SS_VER_1_1 -DSTM32F303xC -DSTM32F3 -DSTM32 -DDEBUG -DHAL_TYPE=HAL_stm32f3 -DPLATFORM=CWLITEARM -DTINYAES128C -DF_CPU=7372800UL -Os -funsigned-char -funsigned-bitfields -fshort-enums -Wall -Wstrict-prototypes -Wa,-adhlns=objdir/simpleserial-aes.o -I.././simpleserial/ -I.././hal -I.././hal/stm32f3 -I.././hal/stm32f3/CMSIS -I.././hal/stm32f3/CMSIS/core -I.././hal/stm32f3/CMSIS/device -I.././hal/stm32f4/Legacy -I.././crypto/ -I.././crypto/tiny-AES128-C -std=gnu99 -MMD -MP -MF .dep/simpleserial-aes-CWLITEARM.elf.d objdir/simpleserial-aes.o objdir/simpleserial.o objdir/stm32f3_hal.o objdir/stm32f3_hal_lowlevel.o objdir/stm32f3_sysmem.o objdir/aes.o objdir/aes-independant.o objdir/stm32f3_startup.o --output simpleserial-aes-CWLITEARM.elf --specs=nano.specs -T .././hal/stm32f3/LinkerScript.ld -Wl,--gc-sections -lm -Wl,-Map=simpleserial-aes-CWLITEARM.map,--cref   -lm  

.

Creating load file for Flash: simpleserial-aes-CWLITEARM.hex

arm-none-eabi-objcopy -O ihex -R .eeprom -R .fuse -R .lock -R .signature simpleserial-aes-CWLITEARM.elf simpleserial-aes-CWLITEARM.hex

.

Creating load file for EEPROM: simpleserial-aes-CWLITEARM.eep

arm-none-eabi-objcopy -j .eeprom --set-section-flags=.eeprom="alloc,load" \

	--change-section-lma .eeprom=0 --no-change-warnings -O ihex simpleserial-aes-CWLITEARM.elf simpleserial-aes-CWLITEARM.eep || exit 0

.

Creating Extended Listing: simpleserial-aes-CWLITEARM.lss

arm-none-eabi-objdump -h -S -z simpleserial-aes-CWLITEARM.elf > simpleserial-aes-CWLITEARM.lss

.

Creating Symbol Table: simpleserial-aes-CWLITEARM.sym

arm-none-eabi-nm -n simpleserial-aes-CWLITEARM.elf > simpleserial-aes-CWLITEARM.sym

Size after:

   text	   data	    bss	    dec	    hex	filename

   5384	    532	   1484	   7400	   1ce8	simpleserial-aes-CWLITEARM.elf

+--------------------------------------------------------

+ Built for platform CW-Lite Arm (STM32F3)

+--------------------------------------------------------

simpleserial-aes.c: In function 'get_pt':

simpleserial-aes.c:42:3: warning: this 'for' clause does not guard... [-Wmisleading-indentation]

   for (volatile uint8_t k = 0; k < (*pt & 0x0F); k++);

   ^~~

simpleserial-aes.c:45:2: note: ...this statement, but the latter is misleadingly indented as if it were guarded by the 'for'

  aes_indep_enc(pt); /* encrypting the data block */

  ^~~~~~~~~~~~~

Setup

Now let's go ahead. We'll have to program the file we built, so be sure to confirm we are using the right file!

In [3]:
%run "Helper_Scripts/Setup.ipynb"
In [4]:
import os, time

fw_path = '../hardware/victims/firmware/simpleserial-aes/simpleserial-aes-{}.hex'.format(PLATFORM)

modtime = os.path.getmtime(fw_path)
print("File build time: {:s} (built {:.2f} mins ago)".format(str(time.ctime(modtime)), (time.time() - modtime)/60.0))
File build time: Wed Jun 26 13:03:43 2019 (built 0.03 mins ago)
In [5]:
cw.program_target(scope, prog, fw_path)
Detected known STMF32: STM32F302xB(C)/303xB(C)
Extended erase (0x44), this can take ten seconds or more
Attempting to programming 5915 bytes at 0x8000000
STM32F Programming flash...
STM32F Reading flash...
Verified flash OK, 5915 bytes

In addition, before we capture our traces, we'll need to create a ChipWhipserer project, since that's what Analyzer expects for an input:

In [6]:
project = cw.create_project("projects/jupyter_test_jittertime.cwp", overwrite = True)

And we can get the class used to hold our traces by:

In [7]:
tc = project.get_new_trace_segment()

Capturing Traces

Below you can see the capture loop. The main body of the loop loads some new plaintext, arms the scope, sends the key and plaintext, then finally records and our new trace into our trace class. We'll also keep track of our keys manually for checking our answer later.

In [8]:
#Capture Traces
from tqdm import tnrange
import numpy as np
import time

ktp = cw.ktp.Basic(target=target)

keys = []
target.init()
for i in tnrange(num_traces, desc='Capturing traces'):
    key, text = ktp.new_pair()  # manual creation of a key, text pair can be substituted here
    ret = cw.capture_trace(scope, target, text, key)
    if ret is None:
        continue
    trace, resp = ret
    tc.add_trace(trace, text, resp, key)

Now that we have our traces, we need to tell the project that the traces are loaded and add them to the project's trace manager.

In [9]:
project.append_segment(tc)

#Save project file
project.save()

We're now done with the ChipWhisperer hardware, so we should disconnect from the scope and target:

In [10]:
# cleanup the connection to the target and scope
scope.dis()
target.dis()

Analysis

To fix the jitter, we'll need to add our traces to a preprocessing module. We can feed project.traceManager() right into attack.setTraceSource(), but we could also add pre-processing inbetween (more about this later). We'll also re-open the traces, in this case it is required since the call to closeAll() would have flushed the buffers.

In [11]:
#Force reload of project data (if you comment out 'closeAll()' this isn't needed)

#We also rebuild the project object in case you only want to run this half
import chipwhisperer as cw
import chipwhisperer.analyzer as cwa
project = cw.open_project("projects/jupyter_test_jittertime.cwp")

This time we're going to do a few things. First we will get the traces, and plot a few of them as-is. You can adjust the traces plotted by adjusting the range(10). For example range(1) plots the first trace.

In [12]:
tm = project.traceManager()

from bokeh.plotting import figure, show
from bokeh.io import output_notebook
from bokeh.palettes import Dark2_5 as palette
import itertools  

output_notebook()
p = figure(sizing_mode='scale_width', plot_height=300)

# create a color iterator
colors = itertools.cycle(palette)  

x_range = range(0, tm.num_points())
for i, color in zip(range(10), colors): #Adjust range(n) to plot certain traces
    p.line(x_range, tm.get_trace(i), color=color)
show(p)
Loading BokehJS ...

So how do we fix that? To begin with, you should plot only a single trace to make your life more clear. You'll need to figure out a very unique area. For example see the following figure showing a single plot. In this example the location of A is unique, but B would have many matches within that same trace, even nearby: Resync example trace

We will specify two items:

  • A window with the "unique" area defined.
  • How far we will shift the window (+/- points) to search for the best match.

You can use the following code to define the target_window and max_shift. Try a few values until you find something that works. Also try some poor example, and also try plotting more traces to confirm your match is working in real life.

In [13]:
resync_traces = cwa.preprocessing.ResyncSAD(tm, connectTracePlot=False)
resync_traces.enabled = True
resync_traces.ref_trace = 0

if PLATFORM == "CWNANO":
    #Define a target window here. 500,900 for example is good based on above. But try some different values.
    resync_traces.target_window = (300, 700)

    # Define max_shift. Must not cause target_window to go outside of valid data. Try 16-600 range. Ideal value varies with how
    # much jitter is in original data. 
    resync_traces.max_shift = 300
elif PLATFORM == "CWLITEXMEGA" or PLATFORM == "CW303":
    #Define a target window here. 500,900 for example is good based on above. But try some different values.
    resync_traces.target_window = (1000, 1400)

    # Define max_shift. Must not cause target_window to go outside of valid data. Try 16-600 range. Ideal value varies with how
    # much jitter is in original data. 
    resync_traces.max_shift = 1000
else:
    #Define a target window here. 500,900 for example is good based on above. But try some different values.
    resync_traces.target_window = (700, 1500)

    # Define max_shift. Must not cause target_window to go outside of valid data. Try 16-600 range. Ideal value varies with how
    # much jitter is in original data. 
    resync_traces.max_shift = 700

#Uses objects from previous cells (plotting etc), so 
output_notebook()
p = figure()

for i, color in zip(range(10), colors):
    p.line(x_range, resync_traces.get_trace(i), color=color)
show(p)

preprocessed_traces = resync_traces
Loading BokehJS ...

If this all works - let's just continue the attack! Do so as below:

In [14]:
leak_model = cwa.AES128()
attack = cwa.cpa(preprocessed_traces, leak_model)

And then actually run it:

In [15]:
cb = cwa.get_jupyter_callback(attack)
attack_results = attack.process_traces(cb)
Finished traces 240 to 250
0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15
PGE= 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0
0 2B
0.920
7E
0.850
15
0.882
16
0.862
28
0.894
AE
0.880
D2
0.906
A6
0.887
AB
0.904
F7
0.887
15
0.902
88
0.894
09
0.901
CF
0.876
4F
0.888
3C
0.877
1 1B
0.315
0B
0.324
03
0.371
26
0.345
35
0.328
2C
0.343
89
0.342
95
0.359
E6
0.392
9F
0.313
0A
0.324
7D
0.373
F3
0.316
29
0.319
BA
0.318
9B
0.315
2 6E
0.304
BF
0.306
2A
0.347
15
0.327
CB
0.297
F7
0.314
22
0.321
DA
0.311
C9
0.314
F4
0.304
61
0.323
5B
0.326
A9
0.305
AF
0.315
BF
0.306
87
0.303
3 59
0.298
C4
0.300
1F
0.329
A6
0.302
0F
0.296
C4
0.312
6F
0.305
D7
0.311
E2
0.314
65
0.293
2B
0.313
8B
0.316
AE
0.299
06
0.308
9B
0.299
8E
0.301
4 03
0.297
04
0.297
D5
0.323
1C
0.287
0C
0.286
AD
0.308
27
0.304
4F
0.296
82
0.305
ED
0.286
0C
0.307
D7
0.312
55
0.287
78
0.303
B9
0.297
CD
0.298

You should see the PGE reach 0 for each byte. If not, you might need to adjust the SAD resync. You could also need to increase the length of the sample capture for example. You may notice that it starts working OK and then fails, due to later traces become unsychronized.

Plotting Correlation Output

In [16]:
from bokeh.plotting import figure, show
from bokeh.io import output_notebook

attack_results = attack.get_statistics()
plot_data = cwa.analyzer_plots(attack_results)
bnum = 0

ret = plot_data.output_vs_time(bnum)

output_notebook()
p = figure()
p.line(ret[0], ret[2], line_color='green')
p.line(ret[0], ret[3], line_color='green')

p.line(ret[0], ret[1], line_color='red')
show(p)
Loading BokehJS ...

You should see a graph of red and green in time (samples). In red is the correlation of the correct subkey for the first byte, while the rest are in green.

You should see two or three distinctive red spikes. The first is the spot where the sbox lookup for the subkey we guessed actually happens (the later ones are from later steps in the AES operation).

What about the rest of the bytes in the key? We can get and plot that easily as well:

In [17]:
rets = []
for i in range(0, 16):
    rets.append(plot_data.output_vs_time(i))

p = figure()
for ret in rets:
    p.line(ret[0], ret[2], line_color='green')
    p.line(ret[0], ret[3], line_color='green')
    
for ret in rets:
    p.line(ret[0], ret[1], line_color='red')

show(p)

Conclusion

Awesome! You should have now completed a resynchronization of power traces. This is a very useful tool, and you can see how making a simple class could extend this work.

Tests

In [18]:
key = project.trace_manager().get_known_key(0)
recv_key = [kguess[0][0] for kguess in attack_results.find_maximums()]
assert (key == recv_key).all(), "Failed to recover encryption key\nGot: {}\nExpected: {}".format(recv_key, key)
In [19]:
assert (attack_results.pge == [0]*16), "PGE for some bytes not zero: {}".format(attack_results.pge)
In [20]:
if CHECK_CORR:
    max_corrs = [kguess[0][2] for kguess in attack_results.find_maximums()]
    assert (np.all([corr > 0.75 for corr in max_corrs])), "Low correlation in attack (corr <= 0.75): {}".format(max_corrs)
In [ ]: